(Reaffirmed 2002)

REFRACTORIES INDUSTRY -

FOR USE IN FOUNDRY RECOMMENDATIONS

ICS

81.080

0 BIS 1997

BUREAU
MANAK

OF

INDIAN

STANDARDS
MARG

BHAVAN,

9 BAHADUR SHAH ZAFAR NEW DELHI 110002

September

1997

Price Group

5

Refractories

Sectional Committee, MTD 15

FOREWORD This Indian Standard was adopted by the Bureau of Indian Standards, after the draft finalized by the Refractories Sectional Committee had been approved by the Metallurgical Engineering Division Council. Refractories are the primary materials used in the construction of all furnaces in the ferrous and non ferrous industries. These are used in the lining of ladles, hot metal mixers, metal retaining vessels and the flues and stacks through which hot gasses pass. Refractories are used for lining of boilers, pressure vessels, kilns and vessels using hot fluids at various temperatures. In short, refractories can be termed as those materials~of construction exposed to high temperatures and corroding atmospheres and they retain their shapes and characteristics wihtout reacting with the molten material or the corroding atmospheres. Refractory materials are costly and a sudden failure of any refractory may result in great loss of time, product and equipment. Therefore, the selection of refractories suitable for a particular application is of paramount importance. Cost-benefit-analysis is often the basis of selection of such refractories. A refractory best suited for an application may not necessarily have the longest life. In selecting the proper refractories, a balance is struck between the initial installed cost and in-service performance. Steel industry uses over 70 percent of the refractories consumed in the country. However, integrated steel plants employ a team of refractory engineers and specialists for selection and use of refractories. On the other hand, non-ferrous sector, the glass industry and the other high temperature and corrosion intensive industries do not always employ refractory specialists. The application of refractories in such industries is nevertheless very critical and any premature failure may lead to long down times and loss of production. With the above problems of unorganized sector in mind, the Refractories Sectional Committee, MTD 15 decided to bring out an Handbook for Refractories which could be used as a reference book by the unorganized sector. The -Refractories Sectional Committee MTD 15 alloted this work to a specially constituted Panel, MTD 15/P - 1 Panel for the Handbook for Refractories, consisting of experts from various fields of activities which the handbook will eventually cover. It is hoped that the work of this panel would lead to improvement of refractory engineering practices and overall conservation of materials and energy. The handbook will first be published in parts as recommendations; each recommendation dealing with particular industry/process. Later on when all recommendations are published, these would be combined to form a handbook. It is intended to cover the refractories used in the following industries in the handbook for refractories: ~a) Refractories b) Refractories c) Refractories d) Refractories e) Refractories for cement kiln systems (large plants); for mini-cement plants; for petroleum and petrochemical for pulp and paper industry; for lime kilns-rotary type and shaft_type; industry;

f) Refractories used in the primary processing of non-ferrous materials such as aluminium, copper, zinc, lead, etc; g) Refractories h) Refractories j) Refractories k) Refractories m) Refractories n) Refractories used in manufacture of ferro-alloys; used in the pouring practices for ferrous and nonferrous materials; for incinerators; used by the ceramic and refractory industry; for the nuclear fuel plant; for the glass industry;
(Continued on third cover)

IS 14447 : 1997

Indian Standard

REFRACTORIESFORUSE IN FOUNDRY RECOMMENDATIONS ' INDUSTRY1 SCOPE

This standard covers the recommendations for refractories generally used in foundary industry. 2 REFERENCES The following Indian Standards listed below are necessary adjuncts to this standard: IS No. 6 : 1983 Title Moderate heat duty fireclay refractories Group `A' yburth revision) Silica refractories for general purposes (second revision) Burnt chrome - magnesite refractories for general purposes chrome - magnesite Burnt refractories for general purposes Glossary of terms relating to refractory materials

484 : 1980 3304 : 1965 3305 : 1965 4041: 1987

refractory bricks or with monolithic material. The lower portion is ringed by a wind box, from which air blast enters the cupola through tuyeres to support combustion. A charging door;usually located some 6 metre above the bottom of the furnace permits loading of the cupola with fuel and the materials making up the charge. Cupolas in general use range from 0.75 to 2.25 metre in inside diameter. In charging, a bed of layer of fuel (coke) is'placed at the bottom of the cupola, and charge alternating thereafter up the stack of the cupola to a predetermined height below the charging door. As combustion proceeds, the molten metal may be may flow into a drawn-off directly and force - hearth for subsequent transfer to an electric furnace or for direct casting. Cupolas are extensively used for the production of cast irons. 5.2 Refractory Practice 5.2.1 Property Requirements The lining material should resistant to: a) high temperature, b) abrasion, c) thermal shock, and d) chemical attack. 5.2.2 Lining Thickness Generally the lining is about 100 mm thick. As the diameter or length of the cupola increases, the lining thickness also increases. 5.2.3 Acid Linings 5.2.3.1 Brick lining High duty fire brick mortar for bonding the refractory lining together generally must have the following properties: a) It must be at least equal in refractoriness to that of-the brick, b) It should have good workability, and c) It should not settle rapidly when mixed with. water. 5.2.3.2 Types of mortars Mortars can be generally classified into: a) hot-setting, and 1 b) air-setting., 1 be such that it is

3 TERMINOLOGY For the purpose of this standard, the definitions given in IS'4041 shall apply. 4 INTRODUCTION In foundaries, where metal is cast to shape by pouring molten metal into moulds, the main use of refractories is for lining the melting furnaces and molten metal handling systems, for example, transfer and pouring ladles, etc, and also heat treatment furnaces. The choice of refractory for melting furnaces and allied liquid metal handling systems depends on the slag/metal chemistry, temperature conditions as well as cost. This standard outlines refractory practice for the melting furnaces commonly used in foundries, namely cupola, rotary furnaces, electric arc furnaces. Electric induction furnaces are also covered to an extent. It also touches upon the lining materials and practice for the different types of ladles in foundries.
SECTION

1

5 CUPOLA 5.1 Description The cupola, is a vertical, cylindrical furnace, as shown in fig. 1, built of steel plates and lined with

IS 14447: 1997

LINING
CHARGING NEED

ABOVE
~00~ BE TO `NOT

t
CHARGING DOOR

I N

JUYERE

OPENINGS

H

[

-SLAG

HOLE

/TAPE

HOLE

FLOOR

LI NE

CONCRETE

BASE

FIG. 1 CROSSSECTIONOF CUPOLASHOWINGLINING These can be further classified as wet or dry forms. These mortars are used for lining of bricks. 5.2.3.3 Monolithic linings 5.2.4.1 Basic mortars
These are generally mixture of fireclay and silica

stone charge also calls for abasic lining. It is usually made of high fired magnesite bricks or chemically bonded magnesite-chrome bricks.

and are applied by the gunning methods. 5.2.4 Basic Lining
The principal reason for use of basic lining is for

nodular iron production. Demand for hotter iron, use of high sulphur fuel and increase in the lime2

In cupolas with less than 225 mm lining thickness 50 or 75 mm thick high duty fireclay brick in the back of the basic lining to compensate for the .higher thermal conductivity is generally used. For more than 225 mm lining thickness it is only necessary to substitute the basic lining for the heavy duty brick inner lining.

IS 14447 : 1997
SECTION 2

6 ROTARY FURNACES 6.1 Description This type of furnace consists of a horizontal cylindrical shell mounted on rollers and lined with refractory material. The furnace is usually tapered at both ends, the burner being at one end and an exhaust by system at the other for waste gases, often in conjuction with a recuperative system for preheating the combustion air. The fuel may be oil, gas or pulverized coal, and the air supplied by a fan or blower. The cross-section of a typical rotary furnace is shown in Fig. 2. 6.1.1 The furnace body is slowly rotated or oscillated during the melting thus bringing the underside of the metal bath into contact with the hot refractory lining. This action prevents lining from getting overheated by the flame and reduces the melting time to about half that of a stationary furnace. 6.1.2 Rotary furnaces range in capacity from 0.5 to 15 tonnes. They are largely used for the production of cast iron and can also be used for melting steels, copper, lead and aluminium alloys. 6.2 Refractory Considerations 6.2.1 Material For various grades of cast iron melting, a monolithic lining, consisting of quartz with a suitable binder is used. This quartz is naturally occurring material and is crushed to various sizes to ensure maximum compaction with a maximum grain size around 6.50 mm. The maxium temperature which these linings can withstand is around 1 650°C approximately. Fireclay of sodium based bentonite is normally recommended as a binder.

Bentonite with a refractoriness of 1 150 to 1350°C and very high shrinkage due to loss of water leads to a poorer campaign life. Fireclaywith a refractoriness of 1650 to 1710°C and lower shrinkage due to loss of water leads to increased lining life. 6.2.2 The typical lining mix consists of the following: a) Quartz material 80 percent by weight grading: Percentage by weight Size -6-Smm 20 40 S-3mm 20 3-2mm 20 - 150 mesh powder b) Binder Fireday (30percent Al2@A&r) 20 percent Moisture 8 - 10 percent Green compression 0.86 - 1 kgf/cm' strength Quartz, along with binder has to be mixed in a suitable muller before taking up for ramming the lining. 6.2.3 Ramming The mixed lining material is rammed by means of pneumatic rammers around metal formers to obtain the contour of the furnace lining. Care must be exercised to ensure that the lining is continuous and ramming is carried out to maximum compaction. The metal formers are withdrawn as the lining proceeds and can be used for subsequent relining of the furnace. 6.2.4 Sintering The main shell and end cores are allowed to air dry for a week and subsequently lined through charcoal and fire wood. The furnace should be taken up for melting after the sintering is over and the melting

FIG. 2 ROTARYFURNACE 3

IS 14447 : 1997 should be carried out continuously to the extent possible under the prevailing working conditions of any set up so as to achieve overall efficiency of the furnace. The sintering cycle should be carried out in the following sequence: a) Air drying. b) Slowheating with charcoal and firewood. C) Assembling burner aide cone with shell. d) Mounting it on roller bed. e) Packing the gap at the joint face with ramming mass. 9 Mounting the exhaust cone and packingthe gap at the joint face with ramming mass. 9) Formation of spouts. h) Heating up of the furnace (see Table 1). Table 1 Sintering Procedure
Heeline Cooling Total Remarks

SECTION

3

7 ELECTRIC ARC FURNACE

7.1 Description The electric arc furnace illustrated-in Fig. 3 can be constructed for acid or basic steel making, melting of cast iron and copper alloys. The basic units of an electric arc furna~ce are carbon as graphite electrodes with an electrode control system, the melting chamber, furnace lining and tilting mechanism. The electrodes are clamped in e&rode holders to which current is supplied. The electrodes move up and down on carriages. The electrodes are arranged at the apices of an equilateral triangle, where they pierce the roof. Water cooled collars or glands are so disposed as to cool the electrodes at this point and seal the opening, thus obviating an excessive chimney effect. The furnace lining which encloses the melting chamber, consists of the hearth, the roof and the side walls. The entire furnace is encased in a robust steel shell directly connected with furnace tilting mechanism which is used for tapping and slag removal. The roof lining is enclosed within a steel ring or frame work which can be detached from the furnace shell. In electric arc furnaces, the heat required for melting and heating the metal is supplied by electric arcs at a temperature exceeding 3 OOO"Cjthe arcs being struck between the electrodes and the metal.

Time(1) 15 min 30 min lh 2h 3h 3h 3h 3h

Time(2) 5 10 15 30 30 30 30 30 min min min min min min min min

Time (3) 20 rnin 1 h 2 h 15 4 h 45 8 h 15 11 h 45 15 h 15 18 h 15

(4)

3h 2h

30 min -

min min min min min min After this 25 kg of glass pieces are' thrown into the furnace to glaze the lining surface. 22 h 15 min 24 h 15 min After this, charge the furnace immediately for melting.

ROOF CONSTRUCTION SILICA OR 7O%TOBOK ALUMINA OR MAGNESITE CHROME BRICK

FUSED CAST BURNED OR CHEMICALLY BOUNDED MACNESSITE 3HROME BASIC BRICK SLAG FOR PRACTICE

SILICA BRICK FOR ACID SLAG PRACTICE

BOTTOM CONSTRUCTION

_rTbAGNESIA FIRECLAY

SILICA DOLOMITE OR MAGNESIA RAMMING REFACTORY

OR BRICK

FIG.3 TYPICALELE~TRICARCFURNACEFORSTEELPRODU~TION 4

IS 14447 : 1997 , 7.2 Refractory Consideration Electric Arc Furnace 7.2.1 Roof 7.2.1.1 Type of bricks These are economical, but due to for Lining of

f)

a> Silica -

g)

their low melting temperature and spalling propensity their campaign life is inferior. High alumina - 70 to 80 percent alumina b) bricks, fired or phosphate bonded, are also used. These refractories have a higher melting point which alloys a much higher temperature of operation. The campaign life is 2 to 3 times that of silica bricks. c> Fired magnesite chrome - These bricks are economical to use only when the furnaces are hard driven.
HIGH ALUMINA

composition - The chemical composition has got to be compatible with the system so that the liquid phases appearing at higher operating temperatures are kept to a minimum. Accuracy of shapes - This minimizes the cutting and dressing necessary during assembly giving a perfect contour which ultimately results in better stability and lower stress.

Chemical

7.2.2.1

Typical properties given in Table 2.
Table 2 Typical Properties
Characteristics I

of roof refractories

are

of Roof Refractories
Requirements High Alumma h

/ 7O%AlzO3 (1) SiOz, percent Al2 03, percent Fez 03, percent PCE (Orton), Min Apparent porosity, percent, MUK CCS, kg/cm2, Min RUL, ta ' C, Min (2 kg/cm5 P.L.C., percent,
MClX

T 8O%AlzO3 (4)
-

(2) 94 Min 1.5 Max 31

(3)
-

70 Min 3.5 Max
36

80 ? 1.5 3.5 Max
36

22' 300
1690

24 225 1500

25 250 1520

+ 1.0
(1450"C/2h)

+ 2.5 + 1.5 (1 SOO'=C/lh) (1600"C/lh)

FIG. 4 ROOFCONSTRUCTIONOFANELE~TRIC ARCFURNACE
Physical and Chemical Property Requirements 7.2.2 of Roof Linings

NOTE - Silica bricks conforming to IS 484 may also bc used. *Bricks with lower apparent porosity are preferred.

7.2.3 LiningProcedure The arc furnace roof has been mostly standardized

a)

Porosily -

The bricks should have a lower

porosity to resist corrosive attacks of fumes and slags. b) Pore Size Distribution - Bricks having fine pores are less vulnerable to low melting liquids formed at working face during operation. C> Thermal Expansion - Slight expansion of the roof bricks on heating is always preferable, whereas a high shrinkage may prove disastrous. d) Refi-actoriness - Higher the refractoriness the higher is the allowable operating temperature.

to dome shaped sprung arch of varying thickness from 150 to 300 mm depending upon the size and capacity the prepared thickness being 230 to 300 mm. The dome shaped bricks are supported either directly by the water cooled metallic roof ring or by special shaped skew back bricks resting on the water cooled ring. The roof bricks are held in position by providing a certain amount of rise which varies SOto 100 mm per metre span for silica to 150 mm for basic bricks. 7.2.3.1 Larger bricks used in roof construction are more prone to spalling than the smaller bricks. The smaller bricks have also an added advantage for the manufacturer to produce them easily with greater accuracy and better properties. They also provide a better scope for distribution allowances during construction which minimizes the stress during the initial heating.
5

e)

Hot Modulus of Rupture, Torsional Creep and Elastici(y - These properties have great

relevance to accommodate normal stresses developing at higher temperatures.

IS 14447 : 1997

FIG. 5 BRIDGE TYPE ROOF OF AN ELECTRIC ARC FURNACE 7.2.3.2 The roof construction into two types: a) Annular ring type. b) Bridge type. is broadly divided The pouring spout is made with aids arch bricks, and the slag door can be constructed with the same size key bricks or with special door jamb blocks near the pillars for bigger furnaces (with mechanical feeding arrangement). It is customary to use ordinary fire bricks as safety lining and burnt magnesite bricks as the working lin_@gupto the sill level. For high power furnaces, where conditions are extremely severe, fused cast magnesite chrome bricks are used in slag lines and hot spots for better life. Dense Magnesite bricks and magnesia carbon bricks are also used for improved life of at the slag level also give improved life of at the slag level also give improved life at the slag level. Above sill level normally magnesite chrome chemically bonded steel bricks are used. 6

These types have also been further rationalized with simpler standard dome shapes for different sizes of roofs and the unwidely shapes hear the delta portion have been avoided by use of good quality ramming masses or plastics. Some typical roof construction details are shown Fig. 3,4 and 5. 7.3 Side Wall 7.3.1 Basic Slag Practice
The side walls of an arc furnace are built with basic

key bricks with a back up lining of fireclay bricks.

IS 14447 : 1997 7.3.2 Acid SIag Practice
These are built of super duty silica brick, often dry with the normal 1 to 100 mm expansion allowance. The door arches and jambs are built of silica, or high alumina refractories to minimize spalling.

7*4. Bank and Bottom 7.4.1 Basic Slag Practice In basic electric arc furnace, the lower side walls near the bank and bottom are lined with 2 to 3 courses of burnt magnesite bricks over the fire bricks safety layer. The magnesite bricks should have high ccs, low porosity and high bulk density. The mode of bottom construction may vary depending on the shape of the shell which may be either spherical or with a flat base tapering up gradually. The construction is generally of stadium type, having steps at different levels. Over these steps, a monolithic basic hearth is rammed pneumatically to give an inverted dome shaped bottom wit sloping banks to hold the liquid metal. The final sintering of the monolith is achieved during the initial heating and melting operation. The shapes of the bank and bottom is maintained by regular fettling and patching. 7.4.2 Acid Slag Practice
The subhearth consists of silica bricks laid dry with

7.3.3 Physical and Chemical Propeqv Requirements
- The bricks must have low porosity to resist penetration of slag and corrosion. b) Bulk density - Since a dense brick is resistant to slag and metal penetration a high bulk density is preferred. C> Refractoriness - Since extremely high temperature prevails in this zone due to arcing, bricks with high refractoriness give better life. 4 Cold crushing strength - Since the mechanical abrasion is severe on the wall during scrap charging, a strong brick having high cold crushing strength is suitable for resisting the erosion. SpallingBricks prone to spalling may peel e) off during temperature fluctuations and for this reason bricks used in the side walls (specially above the sill level) should be spa11resistant in nature. f, Chemical composition - The chemical compatibility of the brick with the process pays a vital role. The liquid phases appearing at high temperatures and due to interaction of the process material with the bricks have to be carefully studied, for example a burnt magnesite brick is compatible with a slag having high Fe0 and CaO content.

a>Porosity

an expansion allowance of 1 mm per 100 mm over 1 or 2 courses of fireclay bricks. The monolithic bottom is made with a mixture of ganister (size 10 mm downwards) plus 10 to 20 percent plastic fireclay and minimum possible water consistent with good ramming quality. The mixture is either sintered into place in layers by means of the arc of completely rammed pneumatically, each layer being roughened before the next is applied. 7.4.3 Typical properties of monolithic refractories for arc furnace bottom are given in Table 4. Table 4 Typical Properties of Monolithic Refractories for Arc Furnace Bottom
Characteristics Requirements (2)

7.3.3.1 Typical properties of side wall refractories are given in Table 3. Table 3 Typical Properties of Wall Refractories
r-Requirements * 7

Characteristics

Chrome Magnesite (Refer IS 3305) (1) _MgO, percent, Min Crz 03, percent, Min Apparent porosity percent, Max
CCS, kg/cm2, Min

Magnetite Chrome (Refer IS 3304) (3)
55

Dense Magnesite

(1) 5F

Magnesite 84 Min Chemically or heat setting o-5 18ooMau

MgO, percent Setting Grading, mm Service temperature, "C

(2)
30

(4)
85

18 24
250

6 24
250 1550

17
600 1550

SECTION

4

7 CORELESS INDUCTION -FURNACE
1600
+ 1.5

RUL, ta"C, Min (2 kg/cm2) P.L.C., percent, Max (1 600°C/2h)

7.1 Principle of Operation The coreless induction furnace operate on the principle that metal could Abemelted by its resistance 7

+ 1.0

+ 1.0

IS 14447: 1997

to the passage of electric current induced within it. The furnace is basically an aircore transformer in which the furnace coil is the primary and the charge to be melted is the secondary. The biggest advantages are its simplicity of construction and easy operation. The coreless crucible, type furnace can also be operated at mains, medium or high frequencies. These are mostly used to melt cast iron and alloys both ferrous and nonferrous of various compositions. 7.2 Construction These types of furnaces constitute essentially a water cooled coil through which high frequency alternating current is passed and a refractory crucible inside which the charge is melted. Typical construction is given in Fig. 6. 7.3 Lining Technique 7.3.1 Dry Method Monolithic Lining with Steel Liner

The water cooled copper coil of the furnace is coated with a suitable refractory mass (70% silica + 30% calcium aluminate). This is a safety measure taken to protect the coil from molten metal in case of a break through. b) Dry ramming mass is thoroughly mixed with requisite quantity of sintering agent such as boric acid). The prepared mass is then thoroughly dried over a light fire in a clean metallic pan for removing the moisture before use. c) Then the furnace coil is insulated with any more of the three insulating materials described in Table 5, and the bottom of the coil is bricked to provide a tight seal. d) Compacting the ramming mass (Typical characteristics are given in Table 6).

a)

FIG. 6 CORELESS INDUCTIONFURNACE

8

IS 14447 : 1997 Table 5 Insulating Materials for Coreless Induction Furnaces [Clause 7.3.1 (c)]
Chernclertslics c Asbestos Requiremenls Ceramic Fibre

-

Moist Felt' (4) Alumina Silicate Silicate gel 1260

(1) Raw material base

(2) Asbestos

(3) Alumina Silicate Fi bre

Twin arm vibrator for furnace size 1 to 8 tonnes. Three arm vibrator for furnace size 6 to 40 tonnes. Four arm vibrator for furnace size 30 to 70 tonnes.

Organic Type of bond Service temperature, 500 1260 "C Max Asbestos, percent, Min 97 34 45 Al2 03, percent 65 54 Si 02, percent Bulk density 0.05 - 0.2 0.24 Min 1.0 - 1.1 kg/cm' Thermal 0.17-0.29 0.08 - 0.22 0.06 - 0.17 conductivity W/m ' K Supply form Plates, board Plates, board, Moist blanket Blanket 3-25mm 2-1omm thick 2 - 25 mm thick thick NOTES 1 Excessive insulating effect is dangerous~since it results in heavy sintering and fettering of the dry monolithic lining and thus in susceptibility to cracking. 2 The surface of the insulating material should be as solid and smooth as possible, to enable the ceramic crucible to expands or shrink freely in accordance with the change of temperature.

NOTE - Farmers used either may be consumable or reusable type. Reusable Former, one place slightly conical former and core angle 1 to 1.5", may be reused by this process.

Table 6 Chemical Composition and Physical Properties of Monolithic Refractories for Coreless Induction Furnace [CZwe 7.3.1 (d)]
Characteristics zzT--xz Requirements

Silica

/

A Magnesite (3) Magnesite Chrome (4)

q

7.3.2 Manual Method a)
The bottom of the crucible is rammed alter-

natively with flat headed and spiked tool, upto a level slightly higher than the specified height. The extra rammed ~material is then scrapped out from the top and the level is checked by a spirit level. Then the mild steel former (in case of reusable former, it is given a very thin oil/graphite/petroleum coat), is placed at the centre and hold in position by wooden wedges. To prevent the former from getting displaced during ramming a heavy weight is placed inside the former. The annular space between the asbestos sheets and steel former is rammed alternately with spiked and flat head rammers from the top. Depending on the size of the furnace, 2 to 4 persons are engaged for hand ramming, the persons are made to rotate continuously till the lining is completed. 2) For the top 75 to 100 mm. Where there is no coil dilute sodium silicate~is added with the ramming mass for developing strength initially after air drying. For the pouring out spout, the mass is also prepared with dilute sodium silicate solution. 3) Compaction by electricvibrations is becoming popular. This is a labour and time saving process, also dust generation is much reduced. Depending on the furnace size the following vibrator are recommended,

(1) (2) 97.5 Min Si 0% percent Al2 03, percent 0.8 Mar Fe2 03, percent 0.6 Max MgO, percent Cr2 03, percent Refractoriness (Orton) 32.5 - 33 Bulk density kg/cm3 2.1- 2.2 (rammed or vibrated) Moisture content, Percent 0.05 - 0.2 (without sintering agent) PLC at 1400 ' Cnh, MU + 4perccnt Setting Chemical Service Temp"C 1650 Mar Typical grain size 30 percent l-5mm 0.06-l mm 50 percent 0 - 0.06 mm 20 percent NOTES

75-85

68-75 7-10

38 Min 2.6-2.65

-

Chemical 1650 Mm o-3

Chemical 1750 - 1800.

1 Basic linings are-used in coreless induction furnaces when a basic reaction with the slag and metal is desired. It can also bc prescribed for melting alloy steels.

2 Silica linings are extensively used for melting of cast iron. It can also be used for melting plain carbon and low alloy steels. 3 For melting of non - ferrous alloys (copper, aluminium and zinc alloys), where operation temperature is low lining with wet ramming mass is done. The ramming mass is mixed with water and additives, and rammed manually or by pneumatic rammers. The former used consists of 3 or 4 detachable pieces which can be easily removed after ramming.

7.3.3 Sintering
The lining is finally consolidated to a monolithic structure by this process. a) Conventional sintering with (lost) melt out formers and consists of the following steps : Inductive heating of former with or. without starting blocks, alternatively

IS I4447 : 1997

thereto, burner heating. Rate of heating 50 to 15O"C/h depending on furnace size. - When the starting blocks or the former begin to melt, addition of clean scrap or liquid charge. - Raising the filled, liquid crucible to sintering temperature, 50°C above working temperature but minimally 1500°C. - Holding at sintering temperature from one to several hours. A-brideged method with (reclaimable) perb) manent former and consists of the following steps: - Preheating former to 450°C in 1 to 2 h which may be done inductively, with burners, or a combination thereof. - Holding at 450°C in 30 to 60 minutes, depending on furnace size. - Rapid cooling of former by compressed air in 15 to 20 minutes. - Removal of former. - Followed by further fast heating with the burner, by 2OOT& or placing of starting blocks and inductive heating, then melting and endeavoring to hold at the desired sintering temperature.
7.4 Lining Repair The monolithic lining can be repaired either after cooling the furnace or in hot condition. After

emptying and cooling the furnace the adhering slag or ~metal at the worn out or cracked zones are chipped off. In case of deep cracks V grooves mare made. Then plastic patching mass (consisting of fine fraction of the same ramming mass plus sodium silicate) is filled into the effected area and a wash of the same material applied. For repairs in the hot condition dry spray guns or slurry guns are used.

7.5 Roof Usually roofrefractories are cast of 50 to 70 percent alumina1 materials or rammed with 60 to 90 percent alumina heat setting plastic ram materials.
SECTION 5 8 LADLES 8.1 Lip Pouring and Teaspout Ladles Following types of refractories are recommended: a) High duty fire brick, b) 50 to 55 percent alumina bricks, c) Silica clay ramming mixes, and d) Plastic refractories containing graphite. 8.2 Bottom Pouring Ladles Following types of refractories are recommended:

Shell lining

-

Fireclay bricks (see IS 6) Quality fireclay (see IS 6) Clay graphite 50 - 55 percent Al2 0s

Stopper rod sleeves Stopper Nozzle -

10

(Continued from second cover)

' p) Refractories

for the glass fibre industry; and for the iron and steel industry. will cover the following aspects of the refractory engineering: systems;

q) Refractories

Each recommendation

a) Process of manufactrue used; b) Types of boilers/furnaces c) Objectives of the refractory lining; d) Design engineering features of the furnaces; e) Principal zones and sections of the furnaces; f) Service conditions in different zones including service temperatures; g) Details of lining used in various zones and sections; h) Refractory installation practices used for the boilers/furnaces; j) Consumption pattern of refractories; k) Application standards, namely Indian and other standards, design codes, stress, considerations, etc; and m) Miscellaneous aspects not covered from (a) to (k). This standard covers the recommendations for refractories use in foundary industry and has five sections covering cupolas, rotary furnaces, electric arc furnaces, coreless induction furnaces and ladles used in the foundries. It is endeavored to cover the principle of operation of the furnace type, constructional details, types of linings, typical properties of linings, recommended refractory materials and the methods used in the Iining of furnaces. For the purpose of deciding whether a particular requirement of this standard is complied with, the final value, observed or calculated, expressing the result of a test or analysis, shall be rounded off in accordance with IS 2 : 1960 `Rules for rounding off numerical values (revised)`. The number of significant places retained in the rounded off value should be the same as that of the specified value in this standard.

Bureau of Indian Standards

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Review of Indian Standards

Amendments are issued to standards as the need arises on the basis of comments. Standards are also reviewed periodically; a standard along with amendments is reaffirmed when such review indicates that no changes are needed; if the review indicates that changes are needed, it is taken up for revision. Users of Indian Standards should ascertain that they are in possession of the latest amendments or edition by referring to the latest issue of~`BIS Handbook' and `Standards: Monthly Additions'. This Indian Standard has been developed from Dot : No. MTD 15 (3354).

Amendments Amend No.

Issued Since Publication

Date of Issue

Text Affected

BUREAU OF INDIAN STANDARDS Headquarters: Manak Bhavan, 9 Bahadur Shah Zafar Marg, New Delhi 110002 Telephones : 323 0131,323 33 75,323 94 02 Regional Offices : Central
: Manak Bhavan, 9 Bahadur Shah Zafar Marg

Telegrams : Manaksanstha (Common to all offices) Telephone 323 76 17 323 38 41 337 84 99,337 85 61 337 86 26,337 9120 60 38 43 60 20 25 235 02 16,235 04 42. 235 15 19,235 23 15, 832 92 95,832 78 58 832 78 9 1,832 78 92

NEW DELHI 110002 Eastern
: l/14 C. I.T. Scheme VII M, V. I. P. Road, Maniktola

CALCUTTA 700054 Northern : SC0 335-336, Sector 34-A, CHANDIGARH 160022

Southern : C. I. T. Campus, IV Cross Road, CHENNAI 600113

Western

: Manakalaya, E9 MIDC, Marol, Andheri (East)

MUMBAI 400093

Branches : AHMADABAD. BANGALORE. BHOPAL. BHUBANESHWAR. COIMBATORE. FARIDABAD. GI-IAZIABAD. GUWAHATI. HYDERABAD. JAIPUR. KANPUR. LUCKNOW. NAGPUR. PATNA. PUNE. THIRUVANANTHAPURAM.
Printed at Printograph, New Delhi, ?h

: 5726847